Astrophysicists have demonstrated that by studying repeated gravitational waves from the same source, they might be able to measure the universe’s expansion accurately.
BY DEBDUTTA PAUL
ಈ ಲೇಖನವನ್ನು ಕನ್ನಡದಲ್ಲಿ ಓದಲು ೨ನೇ ಪುಟಕ್ಕೆ ಹೋಗಿ.
In 1929, astronomers discovered that all galaxies are streaming away from each other. Since they are also flying away from the Earth, the astronomers concluded that the universe is expanding. However, when they measured how fast it is expanding, they got different answers using different methods. The difference continues to be a thorn.
A team of researchers led by Souvik Jana at the International Centre for Theoretical Sciences, Bengaluru, have proposed a solution to the persistent problem. It hinges on studying gravitational waves, ripples in spacetime, which astronomers first detected in 2015. The team studied how gravity itself affects gravitational waves.
As pairs of black holes merge into a single black hole in a cosmic dance, they emit gravitational waves. As they reach the Earth, kilometre-lengthed detectors help scientists study the properties of the black hole pairs, including how far they originated from. The tiny ripples in spacetime that reach the Earth cause measurable changes on these giant detectors, which carry the imprints of the cosmic dance. What’s more, scientists have built a system of these detectors spread across the Earth to make precise measurements of the black holes’ merger.
The space between the black holes and the Earth is not empty, however. Massive galaxies occupying the space between the black holes and the Earth change the paths of these spacetime ripples, resulting in the detectors recording multiple copies of the same waves. Astronomers call this phenomenon gravitational lensing.
“We have been observing the gravitational lensing of light for over a century,” said Parameswaran Ajith, a co-author of the study. “We expect the first observation of lensed gravitational waves in the next few years!”
In the next two decades, scientists will start running advanced gravitational wave detectors in search of the merging black holes. “Future detectors will be able to see out to much larger distances than the existing ones,” explained Shasvath J. Kapadia, from the Inter-University Centre for Astronomy and Astrophysics in Pune, one of the co-authors of the study.
Tejaswi Venumadhav from the University of California at Santa Barbara, another co-author, said they will be able to detect weaker gravitational wave signals that get buried in the noise affecting present detectors.
Astronomers estimate that the advanced detectors will record signals from a few million black hole pairs, each merging to form a mega-black hole. Among these, about 10,000 black hole mergers will appear more than once in the same detector due to gravitational lensing.
The team led by Souvik demonstrated that by counting the number of such repeat black hole mergers and studying the delay between them, they can measure the universe’s expansion rate. As the data from advanced gravitational wave detectors trickle in over the next two decades, their method can potentially measure the universe’s expansion rate accurately.
The team’s proposal, said Souvik, does not require knowing the properties of the individual galaxies which create multiple copies of gravitational waves, the distances to the black hole pairs, or even their exact location in the sky. Instead, it only requires an accurate method of knowing which signals are lensed. Scientists are improving their techniques to identify the repeat signals, adds Shasvath.
Gravitational lensing requires the astronomical source to be far away. The black hole pairs fit this criterion, which can originate a whooping 13.3 billion years ago, barely 500 million years old after the universe’s birth.
Shasvath cautions that their proposed method will be helpful only when the advanced detectors record millions of black hole mergers. Presently, the team is studying how such a future observation will be able to tell apart different models of the universe that cosmologists have proposed.
The models, the team explained, attempt to solve mysteries of the elusive dark matter, a form of matter that does not interact with light. The dark matter hypothesis solves the astronomer’s problem of explaining why galaxies have the observed mass. However, scientists are still unsure of the dark matter’s properties, leading to various dark matter models.
The team’s current work was published in the Physical Review Letters. Their ongoing research suggests that future observations of lensed gravitational waves will serve as a tool to study the properties of dark matter.
The author thanks Parameswaran Ajith for suggestions.